RU2668558C1 - Biological protection container for loading and unloading machine - Google Patents

Abstract

FIELD: nuclear physics; protective devices.SUBSTANCE: invention relates to the field of nuclear power engineering and can be used to protect personnel from radioactive radiation during transport-technological operations during overload with the use of loading and unloading machines (LUM). Biological protection container for the LUM contains a hermetic casing made in the form of a hermetically sealed cylindrical shell with massive flanges, and a biological protection casing fixed to a sealed casing. Body of biological protection is made in the form of a set of elongated wedge-shaped prismatic petals installed parallel to the generatrix of the hermetic body, cross section of each lobe is the shape of an elongated quadrilateral, where its large sides form directions that allow the tabs to be installed back to back with respect to the side surface of an imaginary cylinder covering the maximum area of the source of ionizing radiation.EFFECT: invention makes it possible to eliminate the penetration of radioactive radiation in the places where the elements fixed on the hermetic housing are docked.5 cl, 5 dwg

Description

The invention relates to the field of nuclear energy and can be used primarily to protect personnel from ionizing radiation during transport and technological operations during reloading using unloading and loading machines (REM).

In REM designs, the biological protection container for the spacesuit is traditionally made using mechanically connected massive forgings. However, the production of forgings is a significant cost for the manufacture of a biological protection container in connection with the requirements for their production (stainless inner shell, homogeneous non-porous massive outer structure, the need for mechanical connection of forgings).

One of the ways to possibly reduce the cost of the container is the transition to its manufacture from connected parts: an internal stainless airtight shell and elements built into it that will provide biological protection. Moreover, the design of the container should provide effective protection against ionizing radiation, namely: to guarantee the necessary thickness of biological protection and the inadmissibility of penetration of ionizing radiation at the junctions of biological protection elements.

A well-known container with biological protection for a spacesuit (Loading machines of channel nuclear reactors / S.N. Andreenko, Yu.A. Evseenkov, B.A. Konstantinov, etc. - M., Energoatomizdat, 1986. - 144 p., Ill.), consisting of a fixed biological defense, which is mounted on an REM trolley. The container is a steel cylinder, consisting of several sections, where the sections are interconnected by wedge brackets. An airtight spacesuit is installed inside the container to accommodate REM actuators.

The disadvantage of this known design is that the sections are made in the form of massive elements (forgings), interconnected by mechanical brackets. In addition, this design of the container requires that not only the spacesuit be sealed, but also a steel cylinder consisting of sections, since the control mechanisms pass not only through the biological protection container, but also through the sealed spacesuit, which complicates the design and requires additional costs for its manufacture.

The objective underlying the invention is the development of the design of the biological protection container for rare-earth metals, which provides reliable protection of personnel from ionizing radiation while increasing the manufacturability of the structure, reducing manufacturing costs and operating costs.

To solve this problem, it is proposed to carry out the construction of a biological protection container for rare-earth metals from two connected parts: an internal stainless sealed cylindrical shell and a set of volumetric petals embedded in it, which provide biological protection.

According to the invention:

- sealed housing is made in the form of a sealed cylindrical shell with flanges;

- the lateral surface of the flanges of the sealed cylindrical shell is made of a massive stepped conical surface;

- a set (s) of elongated wedge-shaped prismatic petals mounted (s) on a sealed enclosure parallel to the generatrix of the sealed enclosure;

- the petals are made with a cross section in the form of an elongated tetrahedron, the direction of the large sides of which allows you to set the petals tangent to the side surface of an imaginary cylinder, covering the maximum area of radiation;

- end surfaces of the petals are made stepped conical surface;

- sets of petals are made with the possibility of installation in several rows towards each other.

The technical result consists in eliminating the penetration of ionizing radiation at the junctions of the biological protection elements fixed on the sealed enclosure and this is achieved by installing a set (s) of elongated wedge-shaped prismatic petals that are mounted on the sealed enclosure parallel to its generatrix.

When using the present invention, the following technical results are simultaneously achieved:

- improving the manufacturability of the design due to the implementation of the container from two connected parts;

- reducing manufacturing costs and operating costs by eliminating the use of mechanically joined massive forgings.

The invention, in the particular case of implementation, is illustrated by the following drawings, presented in FIG. 1-5:

FIG. 1 is a general view of a biological protection container for rare-earth metals;

FIG. 2 is a plan view of FIG. one;

FIG. 3 is a section AA in FIG. 2 (container elements);

FIG. 4 is a section BB in FIG. 1 (container elements);

FIG. 5 is a view B in FIG. 4 (container elements).

The biological protection container for rare-earth metals (Figs. 1 and 2) contains an internal sealed housing 1 (Fig. 1), made in the form of a stainless sealed cylindrical shell 2 and flanges 3 (Fig. 3), and a biological protection case 4. The lateral surface of the flange 3 is made of a massive stepped conical surface. On the side surface of the massive flanges 3 of the sealed enclosure 1, a biological protection enclosure 4 is installed (Fig. 1). The body 4 biological protection is made in the form of a set (s) of elongated wedge-shaped prismatic petals 5 (Fig. 3 and 4). The cross section of each petal 5 is the shape of an elongated tetrahedron. In this case, the elongated wedge-shaped prismatic petals 5 are installed end-to-end tangentially to the lateral surface D of an imaginary cylinder with a diameter D (Fig. 4), covering the maximum area of ionizing radiation from the core product (IAP). Thus, when fixing the petal on a sealed cylindrical shell, the large sides G of the tetrahedron in the cross section of the petal 5 form directions that are a continuation of the shape-forming tangent lines to the surface D (Fig. 4). And its small sides E in the cross section of the petal are either straight lines or concentric arcs, coaxial with, for example, surface D (sealed housing). The end surface of each petal 5 is made reciprocal to the side surface of the massive flange 3 with a stepped conical surface W (Fig. 5).

The essence of the proposed design of the biological protection container for rare-earth metals is that petals 5 are sequentially fixed to the sealed cylindrical shell 2 with sections in the form of elongated tetrahedrons, where their large sides form the installation direction along straight lines tangent to surface D, which covers the maximum area of the source ionizing radiation from the IAP. This eliminates the possibility of arranging slits between the petals 5 parallel to the direction of propagation of ionizing radiation. Thus, the IAP is located inside this zone, and the radiation generated by the IAP crosses the petals 5 in the direction of their greatest thickness, thereby providing reliable protection against ionizing radiation in the cross section of the biological protection container for rare-earth metals (Fig. 4). In the longitudinal section of the biological protection container for rare-earth metals (Fig. 3), protection against ionizing radiation is provided by a massive stepped conical surface K (Fig. 3) of the sealed housing 1, which at this point is connected to the end surface W of the petals 5 (Fig. 5).

To increase the reliability of protection against ionizing radiation, the sets of petals 5 can be installed in several rows towards each other (Fig. 4) in a similar way.

The biological protection container for rare-earth metals is mounted as follows.

The cylindrical shell 2 is welded with massive flanges 3. The resulting sealed housing 1 is checked for leaks. Then, the elongated wedge-shaped prismatic petals 5 are successively stacked between the massive flanges 3 so that the side ribs of the prismatic petals 5 are parallel to the generatrix of the cylindrical shell 2. In this case, the ends of the petals 5 are welded, for example, with massive flanges 3 on one side and on the other with a cylindrical shell 2. Thus, sequentially stacked and welded petals 5 form a reliable biological protection.

In the same way, another set of petals 5 is laid in the second row.

The proposed design of a biological protection container for rare-earth metals allows to prevent the penetration of ionizing radiation at the junctions of biological protection elements, which provides reliable protection of personnel from ionizing radiation, as well as improving the manufacturability of the structure, reducing manufacturing costs and operating costs.

Claims (5)

1. The biological protection container for the unloading and loading machine, characterized in that it contains a sealed enclosure made in the form of a sealed cylindrical shell with massive flanges, and a biological protection enclosure mounted on a sealed enclosure, while the biological protection enclosure is made in the form of a set installed in parallel forming a sealed enclosure of elongated wedge-shaped prismatic petals, and the cross section of each petal is an elongated quadrangle, where e large side direction is formed to allow the pitch set to butt on the lateral surface of an imaginary cylinder enclosing the ionizing radiation source is located maximum zone. 2. The device according to claim 1, characterized in that the lateral surface of the flange of the sealed cylindrical shell is made of a massive stepped conical surface. 3. The device according to p. 1, characterized in that the end surfaces of the petals are also made stepped conical surfaces. 4. The device according to 1, characterized in that each set of petals is made with the possibility of installing them in several rows towards each other. 5. The device according to 1, characterized in that the small sides of the tetrahedron in the cross section of the petal are either straight lines or concentric arcs coaxial with the sealed housing.

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